Logan D T, Su X D, Aberg A, Regnström K, Hajdu J, Eklund H, Nordlund P
Department of Molecular Biology University of Stockholm S-106 91 Stockholm Sweden.
Structure. 1996 Sep 15;4(9):1053-64. doi: 10.1016/s0969-2126(96)00112-8.
Ribonucleotide reductases (RNRs) catalyze the formation of the deoxyribonucleotides that are essential for DNA synthesis. The R2 subunit of Escherichia coli RNR is a homodimer containing one dinuclear iron centre per monomer. A tyrosyl radical is essential for catalysis, and is formed via a reaction in which the reduced, diferrous form of the iron centre activates dioxygen. To help understand the mechanism of oxygen activation, we examined the structure of the diferrous form of R2.
The crystal structures of reduced forms of both wild type R2 and a mutant of R2 (Ser211--> Ala) have been determined at 1.7 A and 2.2 A resolution, respectively. The diferrous iron centre was compared to the previously determined structure of the oxidized, diferric form of R2. In both forms of R2 the iron centre is coordinated by the same carboxylate dominated ligand sphere, but in the reduced form there are clear conformational changes in three of the carboxylate ligands and the bridging mu-oxo group and two water molecules are lost. In the reduced form of R2 the coordination number decreases from six to four for both ferrous ions, explaining their high reactivity towards dioxygen. The structure of the mutant Ser211--> Ala, known to have impaired reduction kinetics, shows a large conformational change in one of the neighbouring helices although the iron coordination is very similar to the wild type protein.
Carboxylate shifts are often important for carboxylate coordinated metal clusters; they allow the metals to achieve different coordination modes in redox reactions. In the case of reduced R2 these carboxylate shifts allow the formation of accessible reaction sites for dioxygen. The Ser211--> Ala mutant displays a conformational change in the helix containing the mutation, explaining its altered reduction kinetics.
核糖核苷酸还原酶(RNRs)催化形成DNA合成所必需的脱氧核糖核苷酸。大肠杆菌RNR的R2亚基是一种同型二聚体,每个单体含有一个双核铁中心。酪氨酸自由基对于催化作用至关重要,它通过铁中心的还原二价铁形式激活双氧的反应形成。为了帮助理解氧激活机制,我们研究了R2的二价铁形式的结构。
分别以1.7 Å和2.2 Å的分辨率测定了野生型R2及其突变体(Ser211→Ala)还原形式的晶体结构。将二价铁中心与先前确定的R2氧化三价铁形式的结构进行了比较。在R2的两种形式中,铁中心均由相同的以羧酸盐为主的配体球配位,但在还原形式中,三个羧酸盐配体以及桥连的μ-氧基团和两个水分子发生了明显的构象变化。在R2的还原形式中,两个亚铁离子的配位数均从六降至四,这解释了它们对双氧的高反应活性。已知还原动力学受损的突变体Ser211→Ala的结构显示,尽管铁配位与野生型蛋白非常相似,但相邻螺旋之一发生了大的构象变化。
羧酸盐移位对于羧酸盐配位的金属簇通常很重要;它们允许金属在氧化还原反应中实现不同的配位模式。对于还原的R2,这些羧酸盐移位允许形成双氧可及的反应位点。Ser211→Ala突变体在包含该突变的螺旋中显示出构象变化,这解释了其改变的还原动力学。
